JP3807321B2 - Reference voltage generation circuit, display drive circuit, display device, and reference voltage generation method - Google Patents

Abstract

The present invention provides a reference voltage generation circuit, a display drive circuit, a display device and a reference voltage generation method capable of achieving low power consumption by controlling current flowing to a ladder resistor for generating reference voltage necessary for gray scale display. A reference voltage generation circuit 120 includes a ladder resistor circuit 102. First to i-th ("i" is an integer larger than or equal to 2) reference voltages V1 to Vi are outputted from first to i-th division nodes ND₁ to ND_i which are formed by dividing the ladder resistor circuit by resistor elements R₀ to R_i connected in series. A first switching circuit 104 is inserted between one end of the resistor element R₀ and a first power source line. A second switching circuit 106 is inserted between one end of the resistor element R_i and a second power source line. First to i-th reference voltage output switching circuits VSW1 to VSWi are inserted between the first to i-th division nodes ND₁ to ND_i and first to i-th reference voltage output nodes VND₁ to VND_i. The first and second switching circuits 104 and 106 and on/off state of the first to i - th reference voltage output switching circuits VSW1 to VSWi are controlled by a given switching control signal.

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a reference voltage generation circuit, a display drive circuit, a display device, and a reference voltage generation method.
[0002]
[Background Art and Problems to be Solved by the Invention]
A display device typified by an electro-optical device such as a liquid crystal device is required to be small and have high definition. In particular, a liquid crystal device achieves low power consumption and is often mounted on a portable electronic device. For example, when it is mounted as a display unit of a mobile phone, it is required to display an image rich in color tone by increasing the number of gradations.
[0003]
In general, a video signal for image display is subjected to gamma correction according to display characteristics of the display device. This gamma correction is performed by a gamma correction circuit (reference voltage generation circuit in a broad sense). Taking a liquid crystal device as an example, the gamma correction circuit generates a voltage corresponding to the transmittance of the pixel based on the gradation data for performing gradation display.
[0004]
Such a gamma correction circuit can be configured by a ladder resistor. In this case, the voltage at both ends of each resistance circuit constituting the ladder resistor is output as a multi-level reference voltage corresponding to the gradation value.
[0005]
However, there is a problem that power consumption increases because a current constantly flows through the ladder resistor.
[0006]
The present invention has been made in view of the technical problems as described above, and an object of the present invention is to control a current flowing through a ladder resistor for generating a reference voltage necessary for gradation display. It is an object of the present invention to provide a reference voltage generation circuit, a display drive circuit, a display device, and a reference voltage generation method capable of reducing power consumption.
[0007]
[Means for Solving the Problems]
In order to solve the above-described problems, the present invention is a reference voltage generation circuit that generates a multi-value reference voltage for generating a gamma-corrected gradation value based on gradation data, and is connected in series A ladder resistor circuit having a plurality of resistor circuits and outputting the voltages of the first to i-th (i is an integer of 2 or more) divided nodes divided by each resistor circuit as first to i-th reference voltages; The first switch circuit inserted between the first power supply line to which the first power supply voltage is supplied and one end of the ladder resistor circuit, and the second power supply line to which the second power supply voltage is supplied And a second switch circuit inserted between the other end of the ladder resistor circuit, and the first and second switch circuits are ON / OFF controlled based on the first and second switch control signals. It is characterized by that.
[0008]
Here, the resistance circuit can be configured by, for example, one or a plurality of resistance elements. When the resistance circuit is composed of a plurality of resistance elements, the resistance elements may be connected in series or in parallel. In addition, a switch element connected in series or in parallel with each resistance element may be provided so that the resistance value of the resistance circuit can be variably controlled.
[0009]
When each switch circuit is turned on, it means that both ends of the switch circuit are electrically connected. When each switch circuit is turned off, it means that both ends of the switch circuit are electrically disconnected.
[0010]
In the present invention, the voltage of the divided node divided by the resistance circuits constituting the plurality of ladder resistance circuits is output as a multi-level reference voltage. The ladder resistor circuit is connected between the first and second power supply lines, and a voltage obtained by resistance-dividing the difference between the first and second power supply voltages supplied to the first and second power supply lines, Output from each split node. The voltage output from the divided node is output as a multi-level reference voltage, and is alternatively selected according to, for example, grayscale data, and output to the corresponding signal electrode as a gamma-corrected drive voltage. As described above, since a difference between the first and second power supply voltages is applied to the ladder resistor circuit, a current flows. Therefore, both ends of the ladder resistor circuit are connected to the first and second power supply lines via the first and second switch circuits, and each is turned on and off by the first and second switch control signals. Low power consumption can be achieved.
[0011]
Further, the reference voltage generation circuit according to the present invention is provided between the first to i-th divided nodes and the first to i-th reference voltage output nodes to which the first to i-th reference voltages are output, respectively. The first to i-th reference voltage output switch circuits are inserted, and the first to i-th reference voltage output switch circuits are ON / OFF controlled based on one of the first and second switch control signals. May be.
[0012]
According to the present invention, each divided node and each reference voltage output node are electrically disconnected by the first or second switch control signal that electrically disconnects the ladder resistor circuit. It can be avoided that each reference voltage output node driven by this voltage is electrically connected to another reference voltage output node via a ladder resistor circuit and the voltage is changed. Therefore, it is not necessary to drive each reference voltage output node again to a reference voltage corresponding to the resistance ratio, so that unnecessary charging time can be reduced and power consumption can be further reduced. .
[0013]
In the reference voltage generation circuit according to the present invention, the switch circuit to be controlled is turned on by the first and second switch control signals in a given driving period based on the first to i-th reference voltages. The switch circuit to be controlled may be turned off in a period other than the drive period.
[0014]
According to the present invention, since a multi-valued reference voltage can be generated by flowing a current only when a reference voltage is necessary, current consumption flowing through the ladder resistor circuit can be minimized.
[0015]
In the reference voltage generating circuit according to the present invention, the first and second switch control signals are generated using an output enable signal for controlling driving to the signal electrode and a latch pulse signal indicating a scanning cycle timing. May be.
[0016]
According to the present invention, since the first and second switch control signals are generated by the output enable signal and the latch pulse signal used for the signal driver, current consumption flowing in the ladder resistor circuit without providing an additional circuit Can be suppressed.
[0017]
The reference voltage generation circuit according to the present invention is a partial block for setting a display line of a display panel corresponding to a signal electrode of each block to a display state or a non-display state for each block having a plurality of signal electrodes as a unit. When all the blocks are set to the non-display state according to the selection data, the switch circuit to be controlled may be turned off by the first and second switch control signals.
[0018]
In the present invention, when setting a partial display area and a partial non-display area by a partial block selection data for each block with a given number of signal electrodes as one block, a driving voltage based on gradation data is applied to the signal electrodes. When no output is performed, each switch circuit is turned off by the first and second switch control signals. That is, when all the blocks are set in the partial non-display area by the partial block selection data, it is possible to suppress current consumption flowing through the ladder resistor circuit by turning off each switch circuit.
[0019]
According to another aspect of the present invention, there is provided a display drive circuit including a voltage selection circuit that selects a voltage based on grayscale data from any of the reference voltage generation circuit described above and a multilevel reference voltage generated by the reference voltage generation circuit. And a signal electrode driving circuit that drives the signal electrode using the voltage selected by the voltage selection circuit.
[0020]
According to the present invention, it is possible to reduce power consumption of a display driving circuit that realizes gradation display by performing gamma correction according to given display characteristics.
[0021]
The display drive circuit according to the present invention is a partial block for setting a display line of a display panel corresponding to a signal electrode of each block to a display state or a non-display state for each block having a plurality of signal electrodes as a unit. A partial block selection register for holding selection data, a reference voltage generation circuit as described above for generating a reference voltage for driving a corresponding signal electrode based on the partial block selection data, and generated by the reference voltage generation circuit A voltage selection circuit that selects a voltage from the multi-valued reference voltage based on gradation data, and a signal electrode drive circuit that drives a signal electrode using the voltage selected by the voltage selection circuit. it can.
[0022]
According to the present invention, for a display driving circuit capable of setting a partial display area and a partial non-display area for each block, both gradation display with gamma correction according to given display characteristics and low power consumption can be achieved. Can be made.
[0023]
Further, the display device according to the present invention includes a plurality of signal electrodes, a plurality of scan electrodes intersecting with the plurality of signal electrodes, a pixel specified by the plurality of signal electrodes and the plurality of scan electrodes, The display drive circuit described above for driving the signal electrodes, and the scan electrode drive circuit for driving the plurality of scan electrodes.
[0024]
ADVANTAGE OF THE INVENTION According to this invention, the display apparatus which can make the gradation display which performed the gamma correction | amendment according to the given display characteristic, and low power consumption compatible can be provided.
[0025]
The display device according to the present invention includes a display including a plurality of signal electrodes, a plurality of scanning electrodes intersecting with the plurality of signal electrodes, and a pixel specified by the plurality of signal electrodes and the plurality of scanning electrodes. The display drive circuit described above for driving the panel, the plurality of signal electrodes, and the scan electrode drive circuit for driving the plurality of scan electrodes can be included.
[0026]
ADVANTAGE OF THE INVENTION According to this invention, the display apparatus which can make the gradation display which performed the gamma correction | amendment according to the given display characteristic, and low power consumption compatible can be provided.
[0027]
The present invention also provides a reference voltage generation method for generating a multi-valued reference voltage for generating a gamma-corrected gradation value based on gradation data, each of a plurality of resistor circuits connected in series. Both ends of the ladder resistor circuit that outputs the voltages of the first to i-th (i is an integer of 2 or more) divided nodes divided by the resistor circuit as the first to i-th reference voltages are respectively connected to the first to the first. In a given driving period based on the reference voltage of i, the ladder is electrically connected to the first and second power supply lines to which the first and second power supply voltages are supplied, and in the period other than the driving period, the ladder It is characterized in that both ends of the resistance circuit are electrically disconnected from the first and second power supply lines.
[0028]
In the present invention, from the ladder resistor circuit in which a plurality of resistor circuits are connected in series, the voltages of the first to i-th divided nodes divided by each resistor circuit are output as the first to i-th reference voltages. . The ladder resistor circuit is electrically connected to the first and second power supply lines to which the first and second power supply voltages are supplied only during a given driving period based on the first to i-th reference voltages. Further, both ends of the ladder resistor circuit and the first and second power supply lines are electrically cut off during a period other than the driving period. As a result, in a period in which the reference voltage output from the ladder resistor circuit is not used for driving, current consumption flowing through the ladder resistor circuit can be reduced, so that power consumption can be reduced.
[0029]
In the reference voltage generation method according to the present invention, in the driving period, the first to i-th divided nodes and the first to i-th reference voltage output nodes from which the first to i-th reference voltages are output. And the first to i-th divided nodes and the first to i-th reference voltage output nodes can be electrically disconnected in a period other than the driving period.
[0030]
According to the present invention, since each divided node and each reference voltage output node are electrically cut off during a period in which the reference voltage is not driven, each reference voltage output node once driven is A voltage change caused by being electrically connected to another reference voltage output node via the resistor circuit can be avoided. Therefore, it is not necessary to drive each reference voltage output node again to a reference voltage corresponding to the resistance ratio, so that unnecessary charging time can be reduced and power consumption can be further reduced. .
[0031]
DETAILED DESCRIPTION OF THE INVENTION
DESCRIPTION OF EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. The embodiments described below do not unduly limit the contents of the present invention described in the claims. Also, not all of the configurations described below are essential constituent requirements of the present invention.
[0032]
The reference voltage generation circuit in this embodiment can be used as a gamma correction circuit. This gamma correction circuit is included in the display drive circuit. The display driving circuit can be used for driving an electro-optical device that changes optical characteristics according to an applied voltage, for example, a liquid crystal device.
[0033]
Hereinafter, the case where the reference voltage generation circuit according to this embodiment is applied to a liquid crystal device will be described, but the present invention is not limited to this, and can be applied to other display devices.
[0034]
1. Display device
FIG. 1 shows an outline of the configuration of a display device to which a display drive circuit including a reference voltage generation circuit according to this embodiment is applied.
[0035]
The display device (in a narrow sense, an electro-optical device, a liquid crystal device) 10 can include a display panel (in a narrow sense, a liquid crystal panel) 20.
[0036]
The display panel 20 is formed on a glass substrate, for example. On this glass substrate, a plurality of scanning electrodes (gate lines) G arranged in the Y direction and extending in the X direction respectively. ₁ ~ G _N (N is a natural number of 2 or more) and a plurality of signal electrodes (source lines) S arranged in the X direction and extending in the Y direction. ₁ ~ S _M (M is a natural number of 2 or more). Also, the scan electrode G _n (1 ≦ n ≦ N, where n is a natural number) and the signal electrode S _m (1 ≦ m ≦ M, where m is a natural number), a pixel region (pixel) is provided corresponding to the intersection, and a thin film transistor (hereinafter abbreviated as TFT) 22 is provided in the pixel region. _nm Is arranged.
[0037]
TFT22 _nm The gate electrode of the scanning electrode G _n It is connected to the. TFT22 _nm The source electrode of the signal electrode S _m It is connected to the. TFT22 _nm The drain electrode is a liquid crystal capacitor (liquid crystal element in a broad sense) 24. _nm Pixel electrode 26 _nm It is connected to the.
[0038]
Liquid crystal capacity 24 _nm In the pixel electrode 26, _nm Counter electrode 28 facing _nm A liquid crystal is sealed between the electrodes, and the transmittance of the pixel changes according to the voltage applied between the electrodes. Counter electrode 28 _nm Is supplied with a counter electrode voltage Vcom.
[0039]
The display device 10 can include a signal driver IC 30. As the signal driver IC 30, the display driving circuit in the present embodiment can be used. The signal driver IC 30 receives the signal electrode S of the display panel 20 based on the image data. ₁ ~ S _M Drive.
[0040]
The display device 10 can include a scan driver IC 32. The scan driver IC 32 scans the scan electrode G of the display panel 20 within one vertical scan period. ₁ ~ G _N Are driven sequentially.
[0041]
The display device 10 can include a power supply circuit 34. The power supply circuit 34 generates a voltage necessary for driving the signal electrode and supplies it to the signal driver IC 30. The power supply circuit 34 generates a voltage necessary for driving the scan electrode and supplies it to the scan driver IC 32. Furthermore, the power supply circuit 34 can generate the counter electrode voltage Vcom.
[0042]
The display device 10 can include a common electrode drive circuit 36. The common electrode driving circuit 36 is supplied with the common electrode voltage Vcom generated by the power supply circuit 34 and outputs the common electrode voltage Vcom to the common electrode of the display panel 20.
[0043]
The display device 10 can include a signal control circuit 38. The signal control circuit 38 controls the signal driver IC 30, the scan driver IC 32, and the power supply circuit 34 according to the contents set by a host such as a central processing unit (hereinafter abbreviated as CPU) (not shown). For example, the signal control circuit 38 sets the operation mode to the signal driver IC 30 and the scan driver IC 32, supplies the internally generated vertical synchronization signal and horizontal synchronization signal, and controls the polarity inversion timing to the power supply circuit 34. I do.
[0044]
In FIG. 1, the display device 10 is configured to include the power supply circuit 34, the common electrode drive circuit 36, or the signal control circuit 38, but at least one of these is provided outside the display device 10. You may make it do. Alternatively, the display device 10 can be configured to include a host.
[0045]
In FIG. 1, at least one of a display drive circuit having the function of the signal driver IC 30 and a scan electrode drive circuit having the function of the scan driver IC 32 is formed on the glass substrate on which the display panel 20 is formed. May be.
[0046]
In the display device 10 having such a configuration, the signal driver IC 30 outputs a voltage corresponding to the gradation data to the signal electrode in order to perform gradation display based on the gradation data. The signal driver IC 30 performs gamma correction on the voltage output to the signal electrode based on the gradation data. Therefore, the signal driver IC 30 includes a reference voltage generation circuit (in a narrow sense, a gamma correction circuit) that performs gamma correction.
[0047]
In general, the display panel 20 has different gradation characteristics depending on the structure and the liquid crystal material used. That is, the relationship between the voltage to be applied to the liquid crystal and the transmittance of the pixel is not constant. Therefore, in order to generate an optimum voltage to be applied to the liquid crystal according to the gradation data, gamma correction is performed by the reference voltage generation circuit.
[0048]
In order to optimize the voltage output based on the gradation data, the gamma correction corrects the multi-value voltage generated by the ladder resistor. At that time, the resistance ratio of the resistor circuit constituting the ladder resistor is determined so as to generate a voltage specified by the manufacturer of the display panel 20 or the like.
[0049]
2. Signal driver IC
FIG. 2 is a functional block diagram of the signal driver IC 30 to which the display drive circuit including the reference voltage generation circuit in the present embodiment is applied.
[0050]
The signal driver IC 30 includes an input latch circuit 40, a shift register 42, a line latch circuit 44, a latch circuit 46, a partial block selection register 48, a reference voltage selection circuit (in a narrow sense, a gamma correction circuit) 50, a DAC (Digital / Analog Converter). ) (Voltage selection circuit in a broad sense) 52, output control circuit 54, and voltage follower circuit (signal electrode drive circuit in a broad sense) 56.
[0051]
The input latch circuit 40 latches, for example, gradation data composed of 6-bit RGB signals supplied from the signal control circuit 38 shown in FIG. 1 based on the clock signal CLK. The clock signal CLK is supplied from the signal control circuit 38.
[0052]
The gradation data latched by the input latch circuit 40 is sequentially shifted in the shift register 42 based on the clock signal CLK. The gradation data that is sequentially shifted by the shift register 42 is input to the line latch circuit 44.
[0053]
The gradation data fetched by the line latch circuit 44 is latched by the latch circuit 46 at the timing of the latch pulse signal LP. The latch pulse signal LP is input at the horizontal scanning cycle timing.
[0054]
The partial block selection register 48 holds partial block selection data. Partial block selection data is set via the input latch circuit 40 by a host (not shown). When a plurality of signal electrodes driven by the signal driver IC 30 is, for example, 24 outputs (when one pixel is composed of 3 dots of R, G, and B, 8 pixels), one block is used as the partial block selection data. This is data for setting a display line corresponding to a signal electrode to a display state or a non-display state.
[0055]
FIG. 3A schematically shows a signal driver IC 30 that drives signal electrodes in units of blocks, and FIG. 3B shows an outline of the partial block selection register 48.
[0056]
As shown in FIG. 3A, the signal driver IC 30 has signal electrode drive circuits arranged in the long side direction corresponding to the signal electrodes of the display panel to be driven. The signal electrode drive circuit is included in the voltage follower circuit 56 shown in FIG. The partial block selection register 48 shown in FIG. 3B sets the signal electrode driving circuit for k outputs to, for example, 24 outputs as one block, and sets the display lines corresponding to the signal electrodes to the display state or the non-display state for each block. The partial block selection data to be held is held. Here, the signal electrode drive circuit is divided into blocks B0 to Bj (j is a positive integer equal to or greater than 1), and the partial block selection register 48 receives partial block selection data BLK0_PART ~ corresponding to each block from the input latch circuit 40. BLKj_PART is input. For example, when the partial block selection data BLKz_PART (0 ≦ z ≦ j, z is an integer) is “1”, the display line corresponding to the signal electrode of the block Bz is set to the display state. For example, when the partial block selection data BLKz_PART is “0”, the display line corresponding to the signal electrode of the block Bz is set to the non-display state.
[0057]
The signal driver IC 30 outputs a driving voltage corresponding to the gradation data to the signal electrode of the block set in the display state. Further, for example, a given drive voltage is output to the signal electrode of the block set to the non-display state, and display corresponding to the gradation data is not performed. For example, the display lines corresponding to the signal electrodes of the blocks B0 to Bx0 and Bx1 to Bj are set to the non-display state, and the signals corresponding to the signal electrodes of the blocks Bx0 ′ to Bx1 ′ (x0 ′ = x0 + 1, x1 ′ = x1-1) are set. When the display line is set to the display state, the partial non-display areas 58A and 58B and the partial display area 60 are provided, and the vertical display can be performed on the display panel 20 as shown in FIG.
[0058]
In FIG. 2, the reference voltage generation circuit 50 uses the resistance ratio of the ladder resistance determined so that the gradation expression of the display panel to be driven is optimized, and the power supply voltage (first power supply) on the high potential side. The multi-valued reference voltages V0 to VY (Y is a natural number) generated at the divided node divided by resistance between the voltage V0 and the low-potential-side power supply voltage (second power supply voltage) VSS are output.
[0059]
FIG. 5 shows a diagram for explaining the principle of gamma correction.
[0060]
Here, a diagram of gradation characteristics showing a change in transmittance of a pixel with respect to an applied voltage of liquid crystal is schematically shown. When the transmittance of a pixel is represented by 0% to 100% (or 100% to 0%), generally, the change in transmittance decreases as the applied voltage of the liquid crystal decreases or increases. In the region where the applied voltage of the liquid crystal is near the middle, the change in transmittance is large.
[0061]
Therefore, by performing gamma (γ) correction that performs a change opposite to the above-described change in transmittance, it is possible to realize a gamma-corrected transmittance that changes linearly according to the applied voltage. Therefore, it is possible to generate the reference voltage Vγ that realizes the optimized transmittance based on the gradation data that is digital data. That is, the resistance ratio of the ladder resistor may be realized so that such a reference voltage is generated.
[0062]
The multi-valued reference voltages V0 to VY generated by the reference voltage generation circuit 50 in FIG.
[0063]
The DAC 52 selects one of the multi-valued reference voltages V0 to VY based on the gradation data supplied from the latch circuit 46, and supplies it to the voltage follower circuit (signal electrode driver circuit in a broad sense) 56. Output.
[0064]
The output control circuit 54 performs output control of the voltage follower circuit 56 using the output enable signal XOE for controlling the drive to the signal electrode and the partial block selection data BLK0_PART to BLKj_PART.
[0065]
The voltage follower circuit 56 performs, for example, impedance conversion under the control of the output control circuit 54, and drives the corresponding signal electrode.
[0066]
As described above, the signal driver IC 30 performs impedance conversion for each signal electrode using the voltage selected from the multi-level reference voltage based on the gradation data, and outputs the result.
[0067]
By the way, the reference voltage generation circuit 50 is based on at least one of the output enable signal XOE, the latch pulse signal LP indicating horizontal scanning cycle timing (scanning cycle timing in a broad sense), and partial block selection data BLK0_PART to BLKj_PART. The current flowing through the ladder resistor can be controlled. As a result, it is possible to cause a current to flow through the ladder resistor only during a period in which gradation display based on the generated reference voltage is performed, and it is possible to reduce power consumption.
[0068]
Next, the reference voltage generation circuit 50 will be described in detail.
[0069]
3. Reference voltage generator
FIG. 6 shows a basic configuration of the reference voltage generation circuit 50.
[0070]
The reference voltage generation circuit 50 includes a ladder resistor circuit 70 in which a plurality of resistor circuits are connected in series. Each resistance circuit constituting the ladder resistance circuit 70 can be configured by, for example, one or a plurality of resistance elements. Each resistance circuit can also be configured such that the resistance value is variable by connecting the resistance elements or the resistance elements and one or a plurality of switch elements in series or in parallel.
[0071]
First to i-th (i is an integer of 2 or more) divided nodes ND divided by the resistance circuits of the ladder resistor circuit 70. ₁ ~ ND _i Are output to the first to i-th reference voltage output nodes as multi-valued first to i-th reference voltages V1 to Vi. The DAC 52 is supplied with first to i-th reference voltages V1 to Vi and reference voltages V0 and VY (= VSS).
[0072]
The reference voltage generation circuit 50 includes first and second switch circuits (SW1, SW2) 72 and 74. The first switch circuit 72 is inserted between one end of the ladder resistor circuit 70 and a first power supply line to which a high-potential-side power supply voltage (first power supply voltage) V0 is supplied. The second switch circuit 74 is inserted between the other end of the ladder resistor circuit 70 and a second power supply line to which a low-potential-side power supply voltage (second power supply voltage) VSS is supplied. The first switch circuit 72 is ON / OFF controlled based on the first switch control signal cnt1. The second switch circuit 74 is ON / OFF controlled based on the second switch control signal cnt2. Such first and second switch circuits 72 and 74 can be constituted by, for example, MOS transistors. The first and second switch control signals cnt1 and cnt2 may be generated based on the same given control signal, or may be generated as separate control signals.
[0073]
The reference voltage generating circuit 50 having such a configuration is not driven by using, for example, the first to i-th reference voltages V1 to Vi output from the ladder resistor circuit 70 (based on the first to i-th reference voltages). In a given drive period), by the first and second switch control signals (or the first or second switch control signal when the first and second switch circuits 72 and 74 are controlled by the same switch control signal) By controlling so that the first and second switch circuits 72 and 74 are turned off, current consumption flowing through the ladder resistor circuit 70 can be suppressed.
[0074]
3.1 First configuration example
FIG. 7 shows an outline of the configuration of the reference voltage generation circuit in the first configuration example.
[0075]
The reference voltage generation circuit 100 in the first configuration example includes a ladder resistance circuit 102. The ladder resistor circuit 102 is a resistor circuit (in a narrow sense, a resistor element) R connected in series. ₀ ~ R _i Resistance circuit R ₀ ~ R _i 1st to i-th divided nodes ND divided by resistors ₁ ~ ND _i To 1st to i-th reference voltages Vi are output.
[0076]
In FIG. 7, it is assumed that reference voltages V0 to V63 necessary for displaying 64 gradations are supplied to the DAC. Among these, the reference voltages V <b> 1 to V <b> 62 are output from the ladder resistance circuit 102 of the reference voltage generation circuit 100. That is, the ladder resistor circuit 102 includes a resistor element R connected in series. ₀ ~ R ₆₂ A resistance element R ₀ ~ R ₆₂ 1st to 62nd divided nodes ND divided by resistors ₁ ~ ND ₆₂ To 1st to 62nd reference voltages V1 to V62 are output. Resistance element R ₀ ~ R ₆₂ For example, a resistance ratio determined according to the gradation characteristics shown in FIG. 5 can be realized.
[0077]
The first switch circuit (SW1) 104 includes a resistance element R that constitutes the ladder resistance circuit 102. ₀ Between the first power supply line and the first power supply line. The second switch circuit (SW2) 106 includes a resistance element R constituting the ladder resistance circuit 102. ₆₂ Between the first power source line and the second power supply line. The first and second switch circuits 104 and 106 are controlled by a switch control signal cnt. Here, when the logical level of the switch control signal cnt is “L”, the first and second switch circuits 104 and 106 are turned off to electrically cut off both ends, and the logical level of the switch control signal cnt is “ When “H”, the first and second switch circuits 104 and 106 are turned on to electrically connect both ends.
[0078]
The switch control signal cnt is generated based on the output enable signal XOE, the latch pulse signal LP, and the partial block selection data BLK0_PART to BLKj_PART of each block.
[0079]
When the output enable signal XOE is at the logic level “H”, the voltage follower circuit 56 controlled by the output control circuit 54 sets the output to the signal electrode in a high impedance state. When the output enable signal XOE is at the logic level “L”, the voltage follower circuit 56 controlled by the output control circuit 54 outputs a given drive voltage to the signal electrode. Accordingly, when the output enable signal XOE is at the logic level “H”, the first to 62nd reference voltages V1 to V62 are not used for driving. Therefore, by cutting off the current flowing through the ladder resistor circuit 102 during that period, gamma-corrected gradation display can be performed and the current flowing through the ladder resistor circuit can be minimized.
[0080]
The latch pulse signal LP is a signal that defines, for example, one horizontal scanning cycle timing, and is a signal whose logic level becomes “H” after a given horizontal scanning period. The signal driver IC 30 drives the signal electrode with reference to the falling edge of the latch pulse signal LP. Therefore, when the logic level of the latch pulse signal LP is “H”, the first to 62nd reference voltages V1 to V62 are not used for driving. Therefore, by cutting off the current flowing through the ladder resistor circuit 102 during that period, gamma-corrected gradation display can be performed and the current flowing through the ladder resistor circuit can be minimized.
[0081]
The partial block selection data BLK0_PART to BLKj_PART are data for setting a display line corresponding to the signal electrode of the block to a display state or a non-display state in units of one block with a given number of signal electrodes as a unit. That is, the display line corresponding to the signal electrode of the block set in the non-display state is a partial non-display area, and the signal electrode is not driven using the first to 62nd reference voltages V1 to V62. Therefore, when the display lines corresponding to the signal electrodes of all blocks are set to the non-display state by the partial block selection data BLK0_PART to BLKj_PART (when BLK0_PART to BLKj_PART are all “0” (logic level “L”)), the ladder By blocking the current flowing through the resistor circuit 102, it is possible to perform gamma-corrected gradation display and to minimize the current flowing through the ladder resistor circuit.
[0082]
FIG. 8 shows an example of the control timing of the reference voltage generation circuit 100 in the first configuration example.
[0083]
Here, an example of control timing corresponding to a cycle of inverting the polarity of the voltage applied to the liquid crystal (display element in a broad sense) defined by the polarity inversion signal POL is shown.
[0084]
As described above, the switch control signal cnt can be generated using the output enable signal XOE, the latch pulse signal LP, and the partial block selection data BLK0_PART to BLKj_PART. Based on the switch control signal cnt, the first and second switch circuits 104 and 106 can be on / off controlled. Considering that the signal driver IC 30 drives the signal electrode based on the falling edge of the latch pulse signal LP, the current flows through the ladder resistor circuit 102 only when the logic level of the switch control signal cnt is “H”. Thus, current consumption can be minimized.
[0085]
3.2 Second configuration example
FIG. 9 shows an outline of the configuration of the reference voltage generation circuit in the second configuration example.
[0086]
However, the same parts as those of the reference voltage generation circuit 100 in the first configuration example are denoted by the same reference numerals, and description thereof will be omitted as appropriate.
[0087]
The reference voltage generation circuit 120 in the second configuration example is different from the reference voltage generation circuit 100 in the first configuration example in that the first to i-th divided nodes ND. ₁ ~ ND _i And first to i-th reference voltage output nodes VND that output the first to i-th reference voltages V1 to Vi. ₁ ~ VND _i Between the first to i-th reference voltage output switches VSW1 to VSWi, respectively. The first to i-th reference voltage output switches VSW1 to VSWi are switch control signals cnt for performing on / off control of the first and second switch circuits 104 and 106 (first or second switch control signal in a broad sense). Is turned on / off by.
[0088]
In FIG. 9, it is assumed that reference voltages V0 to V63 necessary for displaying 64 gradations are supplied to the DAC. Among them, the reference voltages V1 to V62 are output from the ladder resistance circuit of the reference voltage generation circuit. That is, the reference voltage generation circuit 120 in the second configuration example is different from the reference voltage generation circuit 100 in the first configuration example in that the first to 62nd divided nodes ND. ₁ ~ ND ₆₂ And first to 62nd reference voltage output nodes VND for outputting 1st to 62nd reference voltages V1 to V62. ₁ ~ VND ₆₂ The first to the 62nd reference voltage output switches VSW1 to VSW62 are inserted between the first and the 62th, respectively. The first to 62nd reference voltage output switches VSW1 to VSW62 are on / off controlled by a switch control signal cnt for performing on / off control of the first and second switch circuits 104 and 106.
[0089]
For example, in the first configuration example as shown in FIG. 7, the first to 62nd divided nodes ND ₁ ~ ND ₆₂ Let us consider a case in which the first and second switch circuits 104 and 106 are turned off in a state in which the first voltage is the original reference voltage V1 to V62. At this time, the voltages of the first to 62nd reference voltage output nodes V1 to V62 are the resistance elements R constituting the ladder resistance circuit 102. ₀ ~ R ₆₂ The current flows through and changes. Therefore, when the first and second switch circuits 104 and 106 are turned on, it is necessary to charge them again until a desired reference voltage is reached.
[0090]
Therefore, as shown in FIG. 9, by providing the first to 62nd reference voltage output switches VSW1 to VSW62, when the first and second switch circuits 104 and 106 are OFF, the 1st to 62nd reference voltages are provided. Output node VND ₁ ~ VND ₆₂ Are the first to 62nd divided nodes ND ₁ ~ ND ₆₂ And the above phenomenon can be avoided. Therefore, for example, the first to 62nd reference voltage output switches VSW1 to VSW62 may be configured to be turned on / off by the switch control signal cnt, similarly to the first and second switch circuits 104 and 106.
[0091]
3.3 Third configuration example
The signal driver IC 30 to which the reference voltage generation circuit is applied drives the signal electrode of the display panel 20 based on the gradation data. A liquid crystal element is provided via a TFT in a pixel region provided corresponding to the intersection of the signal electrode and the scanning electrode of the display panel 20. For the liquid crystal sealed between the pixel electrode and the counter electrode of the liquid crystal element, it is necessary to alternately invert the polarity of the applied voltage of the liquid crystal at a given timing in order to prevent deterioration.
[0092]
Therefore, for the reference voltage generation circuit that generates the reference voltage corresponding to the gradation characteristics, it is necessary to switch the voltage output to the signal electrode based on the same gradation data every time polarity inversion is performed. For this reason, the first and second power supply voltages of the reference voltage generation circuit are alternately switched. However, it is necessary to drive each divided node divided by resistance every time polarity inversion is performed with a given reference voltage, so that charging / discharging is frequently performed and current consumption increases. There's a problem.
[0093]
Therefore, the reference voltage generation circuit 200 of the signal driver IC 30 includes a positive polarity ladder resistor circuit and a negative polarity ladder resistor circuit.
[0094]
FIG. 10 shows an outline of the configuration of the reference voltage generation circuit 200 in the third configuration example.
[0095]
The reference voltage generation circuit 200 in the third configuration example includes a positive ladder resistance circuit 210 and a negative ladder resistance circuit 220. The positive ladder resistance circuit 210 generates reference voltages V1 to Vi used in a positive polarity inversion cycle when the logic level of the polarity inversion signal POL is “H”. The negative ladder resistance circuit 220 generates reference voltages V1 to Vi used in a negative polarity inversion cycle when the logic level of the polarity inversion signal POL is “L”. By providing such two ladder resistor circuits and switching and outputting the reference voltage for each polarity according to a given polarity inversion timing, the optimum reference corresponding to the gradation characteristics that are not generally symmetric characteristics A voltage can be generated, and it is not necessary to switch the power supply voltage between the high potential side and the low potential side.
[0096]
More specifically, the positive-polarity ladder resistor circuit 210 and the negative-polarity ladder resistor circuit 220 each have substantially the same configuration as the reference voltage generation circuit 120 in the second configuration example shown in FIG. However, each switch circuit is ON / OFF controlled using the polarity inversion signal POL. Regardless of the polarity of the voltage applied to the liquid crystal, the high-potential-side and low-potential-side power supply voltages (first and second power supply voltages) are fixed.
[0097]
The positive ladder resistance circuit 210 includes a first ladder resistance circuit 212 in which each resistance circuit is connected in series with a positive resistance ratio. One end of the first ladder resistor circuit 212 is connected to a first power supply line to which a first power supply voltage is supplied via a first switch circuit (SW1) 214. The other end of the first ladder resistor circuit 212 is connected to a second power supply line to which a second power supply voltage is supplied via a second switch circuit (SW2) 216.
[0098]
Each resistance circuit R constituting the first ladder resistance circuit 212 ₀ ~ R _i 1st to i-th divided nodes ND divided by resistors ₁ ~ ND _i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i Between the first to i-th reference voltage output switch circuits VSW1 to VSWi.
[0099]
The first and second switch circuits SW1 and SW2 and the first to i-th reference voltage output switch circuits VSW1 to VSWi are ON / OFF controlled by a switch control signal cnt11 (first switch control signal in a broad sense). The switch control signal cnt11 is generated by a logical product operation of the switch control signal cnt generated as shown in FIG. 9 and the polarity inversion signal POL. That is, the first and second switch circuits SW1 and SW2 and the first to i-th reference voltage output switch circuits VSW1 to VSWi are switched when the logic level of the polarity inversion signal POL is “H”. ON / OFF control according to
[0100]
The negative ladder resistance circuit 220 includes a second ladder resistance circuit 222 in which each resistance circuit is connected in series with a negative resistance ratio. One end of the second ladder resistor circuit 222 is connected to the first power supply line via the third switch circuit (SW3) 224. The other end of the second ladder resistor circuit 222 is connected to the second power supply line via a fourth switch circuit (SW4) 226.
[0101]
Each resistor circuit R constituting the second ladder resistor circuit 222 ₀ ', R _{i + 1} ~ R _2i (I + 1) to 2i divided nodes ND divided by resistors _{i + 1} ~ ND _2i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i (I + 1) to 2ith reference voltage output switch circuits VSW (i + 1) to VSW2i are inserted between the two.
[0102]
The third and fourth switch circuits SW3 and SW4 and the (i + 1) th to 2ith reference voltage output switch circuits VSW (i + 1) to VSW2i are the switch control signal cnt12 (second switch control signal in a broad sense). ) Is on / off controlled. The switch control signal cnt12 is generated by a logical product operation of the switch control signal cnt generated as shown in FIG. 9 and the inverted signal of the polarity inversion signal POL. That is, the third and fourth switch circuits SW3 and SW4 and the (i + 1) th to 2ith reference voltage output switch circuits VSW (i + 1) to VSW2i have the logic level of the polarity inversion signal POL being “L”. On / off control is performed according to the switch control signal cnt.
[0103]
The first to i-th reference voltages V1 to Vi generated by the two ladder resistor circuits and the reference voltages V0 and VY are output to a DAC as a voltage selection circuit.
[0104]
Next, a circuit configuration for driving the signal electrode using the multi-level reference voltage generated by such a reference voltage generation circuit will be described.
[0105]
FIG. 11 shows a specific configuration example of the DAC 52 and the voltage follower circuit 56.
[0106]
Here, only the configuration per output is shown.
[0107]
The DAC 52 can be realized by a ROM decoder circuit. The DAC 52 selects any one of the reference voltages V0 and VY and the first to i-th reference voltages V1 to Vi based on the (q + 1) -bit gradation data, and the voltage follower circuit 56 as the selection voltage Vs. Output to.
[0108]
The voltage follower circuit 56 drives the corresponding signal electrode in accordance with the mode set to either the normal drive mode or the partial drive mode.
[0109]
First, the DAC 52 will be described. The DAC 52 includes (q + 1) -bit gradation data D _q ~ D ₀ And (q + 1) -bit inverted gradation data XD _q ~ XD ₀ Are entered. Inverted gradation data XD _q ~ XD ₀ Is the gradation data D _q ~ D ₀ Are bit-inverted respectively. Here, the gradation data D _q And inverted gradation data XD _q Are the most significant bits of the gradation data and the inverted gradation data, respectively.
[0110]
In the DAC 52, any one of the multi-valued reference voltages V0 to Vi and VY generated by the reference voltage generation circuit is selected based on the gradation data.
[0111]
For example, it is assumed that the reference voltage generation circuit 200 shown in FIG. 10 generates the reference voltages V0 to V63. Reference voltages generated using the positive ladder resistance circuit 210 are V0 ′ to V63 ′. More specifically, the first and second power supply voltages are V0 ′ and V63 ′, and the first to i-th divided nodes ND. ₁ ~ ND _i Is set to V1 ′ to V62 ′.
[0112]
Further, reference voltages generated by using the negative-polarity ladder resistor circuit 220 are V63 ″ to V0 ″. More specifically, the first and second power supply voltages are V63 ″ and V0 ″, and the (i + 1) th to 2ith divided nodes ND. _{i + 1} ~ ND _2i Is set to V62 ″ to V1 ″.
[0113]
That is, it has the following relational expression.
[0114]
V0 ′ = V63 ″ = V0 (1)
V1 ′ = V62 ″ = V1 (2)
V2 ′ = V61 ″ = V2 (3)
...
V61 ′ = V2 ″ = V61 (62)
V62 ′ = V1 ″ = V62 (63)
V63 ′ = V0 ″ = V63 (64)
When the logic level of the polarity inversion signal POL is “H”, 6 (q = 5) -bit gradation data D _Five ~ D ₀ It is assumed that the reference voltage V2 ′ (= V2) generated by the positive polarity ladder resistor circuit 210 is selected corresponding to “000010” (= 2). At this time, when the logic level of the polarity inversion signal POL becomes “L” at the next polarity inversion timing, the gradation data D _Five ~ D ₀ Inverted gradation data XD _Five ~ XD ₀ Use to select the reference voltage. That is, the inverted gradation data XD _Five ~ XD ₀ Becomes “111101” (= 61), and the reference voltage V61 ″ generated by the ladder resistance circuit 220 for negative polarity can be selected. Therefore, in both the positive polarity and the negative polarity, since the second reference voltage V2 is output as shown by the expression (3), it is not necessary to repeatedly charge and discharge the reference voltage output node.
[0115]
The selection voltage Vs selected by the DAC 52 in this way is input to the voltage follower circuit 56.
[0116]
The voltage follower circuit 56 includes switch circuits SWA to SWD and an operational amplifier OPAMP. The output of the operational amplifier OPAMP is connected to the signal electrode output node via the switch circuit SWD. The signal electrode output node is connected to the inverting input terminal of the operational amplifier OPAMP. The signal electrode output node is connected to the non-inverting input terminal of the operational amplifier OPAMP via the switch circuit SWC. An output of an inverter circuit that inverts the polarity inversion signal POL is connected to the signal electrode output node via the switch circuit SWB. Further, the signal electrode output node is connected to the signal line of the most significant bit of the gradation data selected according to the polarity of the driving period defined by the polarity inversion signal POL via the switch circuit SWA.
[0117]
The switch circuit SWA is on / off controlled by a switch control signal ca. The switch circuit SWB is on / off controlled by a switch control signal cb. The switch circuit SWC is on / off controlled by a switch control signal cc. The switch circuit SWD is on / off controlled by a switch control signal cd.
[0118]
Such a voltage follower circuit 56 drives the signal electrode using the operational amplifier OPAMP based on the selection voltage Vs in the normal drive mode. In the partial drive mode, the voltage follower circuit 56 is driven using the polarity inversion signal POL, or performs eight-color display using the most significant bit of the gradation data.
[0119]
FIG. 12A shows switch states in the switch circuits SWA to SWD in each of the above modes. FIG. 12B shows an example of a circuit for generating the switch control signals ca to cb.
[0120]
In the normal drive mode, the signal electrode output node is driven by the operational amplifier OPAMP during the operational amplifier drive period, and the selection voltage Vs output from the DAC 52 is output as it is by bypassing the operational amplifier OPAMP during the resistance output drive period. Therefore, with the switch circuits SWA and SWB turned off, the switch circuit SWD is turned on and the switch circuit SWC is turned off in the operational amplifier drive period, and the switch circuit SWD is turned off and the switch circuit SWC is turned on in the resistance output period.
[0121]
FIG. 13 shows an example of operation timing in the normal drive mode in the voltage follower circuit 56.
[0122]
The switch circuits SWC and SWD are controlled by a control signal DrvCnt. A control signal DrvCnt generated by a control signal generation circuit (not shown) is in the first half period (a given period at the beginning of the drive period) t1 and the second half period t2 of the selection period (drive period) t defined by the latch pulse signal LP. The logic level changes. When the logic level of the control signal DrvCnt becomes “L” in the first half period t1, the switch circuit SWD is turned on and the switch circuit SWC is turned off. Further, when the logic level of the control signal DrvCnt becomes “H” in the second half period t2, the switch circuit SWD is turned off and the switch circuit SWC is turned on. Therefore, in the selection period t, in the first half period t1, the signal electrode is driven by impedance conversion by the operational amplifier OPAMP connected in the voltage follower, and in the second half period t2, the signal electrode is driven using the selection voltage Vs output from the DAC 52. The
[0123]
By driving in this way, in the first half period t1 required for charging the liquid crystal capacitance, the wiring capacitance, etc., the driving voltage Vout is raised at high speed by the operational amplifier OPAMP connected to the voltage follower having high driving capability, and high driving capability. In the latter half period t2 where no signal is required, the DAC 52 can output a drive voltage. Accordingly, it is possible to minimize the operation period of the operational amplifier OPAMP that consumes a large amount of current and to reduce the consumption, and to avoid the situation where the selection period t becomes short due to the increase in the number of lines and the charging period becomes insufficient. Can do.
[0124]
In the partial drive mode shown in FIG. 12A, 8-color display or POL drive is performed in the partial non-display area. In the 8-color display, the corresponding signal electrode is driven using only the most significant bit of the gradation data. Therefore, the switch circuit SWA is turned on and the switch circuit SWB is turned off while the switch circuits SWC and SWD are turned off.
[0125]
Therefore, if one pixel is composed of R, G, and B signals, one pixel is 2 ^Three Gradation display is performed. That is, while displaying a desired moving image or still image in the partial display area, it is possible to display an image with various display colors in the partial non-display area set as the background.
[0126]
Furthermore, in the POL drive in the partial drive mode shown in FIG. 12A, black display or white display can be performed by applying a voltage corresponding to the polarity using the polarity inversion signal POL. Therefore, the switch circuit SWB is turned on and the switch circuit SWA is turned off while the switch circuits SWC and SWD are turned off.
[0127]
In this case, a desired moving image or still image is displayed in the partial display area, while the background color is displayed in black or white, thereby realizing easy-to-view image display. At the same time, no DC component is applied to the liquid crystal in the non-display area, and the liquid crystal can be prevented from deteriorating.
[0128]
Various control signals for controlling the voltage follower circuit 56 can be generated by a circuit as shown in FIG. When the logic level of the 8-color display mode signal 8CMOD is “H”, it indicates that the 8-color display is in the partial drive mode. Whether or not 8-color display is performed is set by a host (not shown), for example. When the logic level of the POL drive mode signal POLMOD is “H”, it indicates that the POL drive is in the partial drive mode. Whether or not to perform POL driving is set by a host (not shown), for example.
[0129]
As described above, the switch control signals ca to cd can be generated using the various signals 8CMOD, POLMOD, and DrvCnt. In addition, when the display line corresponding to the signal electrode driven by the voltage follower circuit 56 belongs to the block set to the non-display state, 8-color display or POL drive is performed, and when the block set to the display state belongs In order to perform normal driving, masking is performed by partial block selection data BLKz_PART corresponding to the block Bz.
[0130]
Further, the voltage follower circuit 56 can set its output to a high impedance state by an output enable signal XOE. Therefore, various control signals are masked by the output enable signal XOE. That is, when the logic level of the output enable signal XOE is “H”, the switch control signals ca to cd control each switch circuit to be controlled to OFF.
[0131]
In the third configuration example, the first to fourth switch circuits are provided between the first and second ladder resistor circuits 212 and 222 and the first and second power supply lines. These can be omitted. In this case, since it is not necessary to switch the first and second power supply voltages alternately by polarity inversion driving, it is not necessary to secure the charging time of each divided node, and the resistance value of the ladder resistor circuit is increased to reduce the current. can do.
[0132]
3.4 Fourth configuration example
The reference voltage generation circuit in the fourth configuration example has a ladder resistance circuit in which the total resistance is high resistance and low resistance for each of positive polarity and negative polarity.
[0133]
FIG. 14 shows an outline of the configuration of the reference voltage generation circuit 300 in the fourth configuration example.
[0134]
That is, the total resistance is the same as that of the low resistance ladder resistor circuit for positive polarity (first low resistance ladder resistor circuit in a broad sense) 310 used when the total resistance is 20 kΩ, for example, and the applied voltage of the liquid crystal is positive. For example, a negative resistance low resistance ladder resistor circuit (second low resistance ladder resistor circuit in a broad sense) 320 used when the applied voltage of the liquid crystal is negative. Also, the total resistance is the same as the high resistance ladder resistance circuit for positive polarity (first high resistance ladder resistance circuit in a broad sense) 330 used when the total resistance is 90 kΩ, for example, and the applied voltage of the liquid crystal is positive. For example, a high-resistance ladder resistance circuit for negative polarity (second high-resistance ladder resistance circuit in a broad sense) 340 used when the applied voltage of the liquid crystal is negative.
[0135]
The positive polarity low resistance ladder resistor circuit 310 and the positive polarity high resistance ladder resistor circuit 330 have the same configuration as the positive polarity ladder resistor circuit 210 shown in FIG. The negative polarity low resistance ladder resistor circuit 320 and the negative polarity high resistance ladder resistor circuit 340 have the same configuration as the negative polarity ladder resistor circuit 220 shown in FIG. However, each switch circuit is on / off controlled using switch control signals cnt11 and cnt12 and timer count signals (control period designation signals in a broad sense) TL1 and TL2. Regardless of the polarity of the voltage applied to the liquid crystal, the high-potential-side and low-potential-side power supply voltages (first and second power supply voltages) are fixed.
[0136]
The positive resistance low resistance ladder resistor circuit 310 includes a first ladder resistor circuit 312 having a total resistance of 20 kΩ, for example, and each resistor circuit connected in series with a positive resistance ratio. One end of the first ladder resistor circuit 312 is connected to a first power supply line to which a first power supply voltage is supplied via a first switch circuit (SW1) 314. The other end of the first ladder resistor circuit 312 is connected to a second power supply line to which a second power supply voltage is supplied via a second switch circuit (SW2) 316.
[0137]
Each resistance circuit R constituting the first ladder resistance circuit 312 ₀ ~ R _i 1st to i-th divided nodes ND divided by resistors ₁ ~ ND _i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i Between the first to i-th reference voltage output switch circuits VSW1 to VSWi.
[0138]
The first and second switch circuits SW1 and SW2 and the first to i-th reference voltage output switch circuits VSW1 to VSWi are on / off controlled by a switch control signal cntPL (first switch control signal in a broad sense). The switch control signal cntPL is generated using the switch control signal cnt11 generated as shown in FIG. 10 and the timer count signals TL1 and TL2. That is, when the logic level of the timer count signal TL1 is “H” and the logic level of the timer count signal TL2 is “L”, on / off control is performed according to the switch control signal cnt11.
[0139]
The low-resistance ladder resistance circuit 320 for negative polarity has a second ladder resistance circuit 322 in which the total resistance is 20 kΩ, for example, and each resistance circuit is connected in series with a resistance ratio for negative polarity. One end of the second ladder resistor circuit 322 is connected to a first power supply line to which a first power supply voltage is supplied via a third switch circuit (SW3) 324. The other end of the second ladder resistor circuit 322 is connected to a second power supply line to which a second power supply voltage is supplied via a fourth switch circuit (SW4) 326.
[0140]
Each resistance circuit R constituting the second ladder resistance circuit 322 ₀ ', R _{i + 1} ~ R _2i (I + 1) to 2i divided nodes ND divided by resistors _{i + 1} ~ ND _2i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i (I + 1) to 2ith reference voltage output switch circuits VSW (i + 1) to VSW2i are inserted between the two.
[0141]
The third and fourth switch circuits SW3 and SW4 and the (i + 1) th to 2ith reference voltage output switch circuits VSW (i + 1) to VSW2i are based on a switch control signal cntML (second switch control signal in a broad sense). ON / OFF controlled. The switch control signal cntML is generated using the switch control signal cnt12 generated as shown in FIG. 10 and the timer count signals TL1 and TL2. That is, when the logic level of the timer count signal TL1 is “H” and the logic level of the timer count signal TL2 is “L”, on / off control is performed according to the switch control signal cnt11.
[0142]
The high resistance ladder resistance circuit 330 for positive polarity has a third ladder resistance circuit 332 in which the total resistance is, for example, 90 kΩ, and each resistance circuit is connected in series with a resistance ratio for positive polarity. One end of the third ladder resistor circuit 332 is connected to a first power supply line to which a first power supply voltage is supplied via a fifth switch circuit (SW5) 334. The other end of the third ladder resistor circuit 332 is connected to a second power supply line to which a second power supply voltage is supplied via a sixth switch circuit (SW6) 336.
[0143]
Each resistor circuit R constituting the third ladder resistor circuit 332 ₀ ', R _{2i + 1} ~ R _3i (2i + 1) to 3i divided nodes ND divided by resistors _{2i + 1} ~ ND _3i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i Are inserted (2i + 1) to 3i reference voltage output switch circuits VSW (2i + 1) to VSW3i.
[0144]
The fifth and sixth switch circuits SW5 and SW6, and the (2i + 1) to 3i reference voltage output switch circuits VSW (2i + 1) to VSW3i are based on a switch control signal cntPH (third switch control signal in a broad sense). ON / OFF controlled. The switch control signal cntPH is generated using the switch control signal cnt11 generated as shown in FIG. 10 and the timer count signals TL1 and TL2. That is, when the logic level of the timer count signal TL1 is “L” and the logic level of the timer count signal TL2 is “H”, on / off control is performed according to the switch control signal cnt11.
[0145]
The high-resistance ladder resistance circuit 340 for negative polarity has a fourth ladder resistance circuit 342 in which the total resistance is, for example, 90 kΩ, and each resistance circuit is connected in series with a resistance ratio for negative polarity. One end of the fourth ladder resistor circuit 342 is connected to a first power supply line to which a first power supply voltage is supplied via a seventh switch circuit (SW7) 344. The other end of the fourth ladder resistor circuit 342 is connected to a second power supply line to which a second power supply voltage is supplied via an eighth switch circuit (SW8) 346.
[0146]
Each resistor circuit R constituting the fourth ladder resistor circuit 342 ₀ "", R _{3i + 1} ~ R _4i (3i + 1) to 4i divided nodes ND divided by resistors _{3i + 1} ~ ND _4i And the first to i-th reference voltage output nodes VND ₁ ~ VND _i (3i + 1) to 4ith reference voltage output switch circuits VSW (3i + 1) to VSW4i are inserted between
[0147]
The seventh and eighth switch circuits SW7, SW8 and the (3i + 1) to 4i reference voltage output switch circuits VSW (3i + 1) to VSW4i are based on a switch control signal cntPH (fourth switch control signal in a broad sense). ON / OFF controlled. The switch control signal cntPH is generated using the switch control signal cnt12 generated as shown in FIG. 10 and the timer count signals TL1 and TL2. That is, when the logic level of the timer count signal TL1 is “L” and the logic level of the timer count signal TL2 is “H”, on / off control is performed according to the switch control signal cnt12.
[0148]
FIG. 15 shows an example of the control timing of the reference voltage generation circuit 300 shown in FIG.
[0149]
Here, with respect to the first reference voltage V1, the control timing when the polarity inversion drive is performed with the positive polarity is shown.
[0150]
The signal driver IC including the reference voltage generation circuit 300 starts driving based on the falling edge of the latch pulse signal LP that defines the horizontal scanning cycle timing. In the driving period, the reference voltage generation circuit 300 uses the positive polarity high resistance ladder resistance circuit 330 and the negative polarity high resistance ladder resistance circuit 340. In the first control period of the driving period, the positive polarity low resistance ladder resistor circuit 310 and the negative polarity low resistance ladder resistor circuit 320 are also used. That is, the high-resistance ladder resistance circuit 330 for positive polarity, the high-resistance ladder resistance circuit 340 for negative polarity, the low-resistance ladder resistance circuit 310 for positive polarity, and the low-resistance ladder resistance circuit 320 for negative polarity are used in the control period. become.
[0151]
Thus, since a current flows through the low resistance ladder resistor circuit during the control period, it is not necessary to control the high resistance ladder resistor circuit.
[0152]
The control period is defined by a control signal DrvCnt as shown in FIG. That is, as shown in FIG. 13, after the operational amplifier drive is performed by the voltage follower circuit 56, the resistance output drive is performed.
[0153]
As described above, in the fourth configuration example, after the operational amplifier is driven using the low resistance ladder resistor circuit, the resistor output drive is performed, and thereafter, the reference voltage V1 is generated by the high resistance ladder resistor circuit. In this way, when resistance output driving by a high resistance ladder resistor circuit is performed after driving an operational amplifier, there may be a case where sufficient charging time cannot be secured to raise the divided node to the first reference voltage V1. The charging time can be ensured by performing the resistance output driving by the low resistance ladder resistor circuit after the operational amplifier driving. Further, by subsequently generating a reference voltage using a high resistance ladder resistor circuit, the current flowing through the ladder resistor circuit can be reduced, and power consumption can be reduced.
[0154]
In the third configuration example, the first to eighth switch circuits SW1 to SW8 are provided between the first to fourth ladder resistor circuits 312, 322, 332, and 342 and the first and second power supply lines. However, these can be omitted. In this case, since it is not necessary to switch the first and second power supply voltages alternately by polarity inversion driving, it is not necessary to secure the charging time of each divided node, and the resistance value of the ladder resistor circuit is increased to reduce the current. can do.
[0155]
4). Other
In the above, a liquid crystal device including a liquid crystal panel using TFTs has been described as an example. However, the present invention is not limited to this. The reference voltage generated by the reference voltage generation circuit 50 may be changed to a current by a given current conversion circuit and supplied to a current-driven element. In this way, for example, the present invention can be applied to a signal driver IC that displays and drives an organic EL panel including an organic EL element provided corresponding to a pixel specified by a signal electrode and a scanning electrode. In particular, in the organic EL panel, when polarity inversion driving is not performed, the reference voltage generation circuit in the first and second configuration examples can be used.
[0156]
FIG. 16 shows an example of a two-transistor pixel circuit in an organic EL panel driven by such a signal driver IC.
[0157]
The organic EL panel has a signal electrode S _m And scan electrode G _n Driving TFT 800 at the intersection with _nm And switch TFT810 _nm And holding capacitor 820 _nm And organic LED830 _nm And have. Driving TFT 800 _nm Is constituted by a p-type transistor.
[0158]
Driving TFT 800 _nm And organic LED830 _nm Is connected in series with the power line.
[0159]
Switch TFT810 _nm The driving TFT 800 _nm Gate electrode and signal electrode S _m Inserted between. Switch TFT810 _nm The gate electrode of the scanning electrode G _n Connected to.
[0160]
Holding capacitor 820 _nm The driving TFT 800 _nm Between the gate electrode and the capacitor line.
[0161]
In such an organic EL element, the scanning electrode G _n Is driven to switch TFT810 _nm Is turned on, the signal electrode S _m Is the holding capacitor 820 _nm And driving TFT 800 _nm Applied to the gate electrode. Driving TFT 800 _nm The gate voltage Vgs of the signal electrode S _m Depends on the voltage of the driving TFT 800 _nm The current that flows through is determined. Driving TFT 800 _nm And organic LED830 _nm Is connected in series with the driving TFT 800 _nm The current that flows through the organic LED 830 _nm The current that flows in
[0162]
Therefore, holding capacitor 820 _nm Signal electrode S _m By holding the gate voltage Vgs according to the voltage of the current, for example, during one frame period, the current corresponding to the gate voltage Vgs is changed to the organic LED 830. _nm The pixel that continues to shine in the frame can be realized.
[0163]
FIG. 17A shows an example of a 4-transistor pixel circuit in an organic EL panel driven using a signal driver IC. FIG. 17B shows an example of the display control timing of this pixel circuit.
[0164]
Also in this case, the organic EL panel has a driving TFT 900. _nm And switch TFT 910 _nm And holding capacitor 920 _nm And organic LED 930 _nm And have.
[0165]
A difference from the two-transistor pixel circuit shown in FIG. 16 is that a p-type TFT 940 as a switching element instead of a constant voltage is used. _nm Through a constant current source 950 _nm And a p-type TFT 960 as a switch element on the power line. _nm Through the holding capacitor 920 _nm And driving TFT 900 _nm It is a point to connect with.
[0166]
In such an organic EL element, first, the p-type TFT 960 is turned off by the gate voltage Vgp to cut off the power supply line, and the p-type TFT 940 is cut by the gate voltage Vsel. _nm And switch TFT910 _nm And turn on the constant current source 950 _nm The constant current Idata from the drive TFT 900 _nm Shed.
[0167]
Driving TFT900 _nm Until the current flowing through the capacitor stabilizes, the holding capacitor 920 _nm Holds a voltage corresponding to the constant current Idata.
[0168]
Subsequently, the p-type TFT 940 is driven by the gate voltage Vsel. _nm And switch TFT910 _nm And p-type TFT 960 by gate voltage Vgp _nm Turn on the power line and driving TFT900 _nm And organic LED 930 _nm Are electrically connected. At this time, the holding capacitor 920 _nm Due to the voltage held in the organic LED 930, the current is substantially equal to the constant current Idata or a magnitude corresponding to the constant current Idata. _nm To be supplied.
[0169]
In such an organic EL element, for example, the scanning electrode can be configured as an electrode to which the gate voltage Vsel is applied, and the signal electrode can be configured as a data line.
[0170]
In the organic LED, a light emitting layer may be provided on the transparent anode (ITO), and a metal cathode may be provided on the light emitting layer. A light emitting layer, a light transmitting cathode, and a transparent seal may be provided on the metal anode. However, the present invention is not limited to the element structure.
[0171]
By configuring the signal driver IC that displays and drives the organic EL panel including the organic EL element as described above as described above, it is possible to provide a signal driver IC that is used for the organic EL panel for general purposes.
[0172]
In addition, this invention is not limited to embodiment mentioned above, A various deformation | transformation implementation is possible within the range of the summary of this invention. For example, it can be applied to a plasma display device.
[0173]
Furthermore, the present invention is not limited to the configuration of the resistor circuit and the switch circuit in the above-described embodiment. As the resistance circuit, one or a plurality of resistance elements can be connected in series or in parallel. Alternatively, the resistance element 1 or a plurality of switch circuits may be connected in series or in parallel so that the resistance value becomes variable. The switch circuit can be constituted by, for example, a MOS transistor.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an outline of a configuration of a display device to which a display drive circuit including a reference voltage generation circuit is applied.
FIG. 2 is a functional block diagram of a signal driver IC to which a display drive circuit including a reference voltage generation circuit is applied.
FIG. 3A is a schematic diagram of a signal driver IC that drives signal electrodes in units of blocks. FIG. 3B is an explanatory diagram showing an outline of the partial block selection register.
FIG. 4 is an explanatory diagram schematically showing vertical band partial display.
FIG. 5 is an explanatory diagram for explaining the principle of gamma correction.
FIG. 6 is a configuration diagram showing a basic configuration of a reference voltage generating circuit.
FIG. 7 is a configuration diagram showing an outline of a configuration of a reference voltage generating circuit in a first configuration example.
FIG. 8 is a timing chart showing an example of control timing of the reference voltage generation circuit in the first configuration example.
FIG. 9 is a configuration diagram showing an outline of a configuration of a reference voltage generation circuit in a second configuration example;
FIG. 10 is a configuration diagram showing an outline of a configuration of a reference voltage generation circuit in a third configuration example.
FIG. 11 is a configuration diagram illustrating a specific configuration example of a DAC and a voltage follower circuit.
FIG. 12A is an explanatory diagram showing the switch state of the switch circuit in each mode. FIG. 12B is a circuit diagram illustrating an example of a switch control signal generation circuit.
FIG. 13 is a timing chart showing an example of operation timing in the normal drive mode in the voltage follower circuit.
FIG. 14 is a configuration diagram showing an outline of a configuration of a reference voltage generation circuit in a fourth configuration example.
FIG. 15 is a timing chart illustrating an example of control timing of a reference voltage generation circuit according to a fourth configuration example.
FIG. 16 is a configuration diagram illustrating an example of a two-transistor pixel circuit in an organic EL panel.
FIG. 17A is a circuit configuration diagram illustrating an example of a four-transistor pixel circuit in an organic EL panel. FIG. 17B is a timing chart showing an example of display control timing of the pixel circuit.
[Explanation of symbols]
10 Display device
20 Display panel
22 _nm TFT
24 _nm LCD capacity
26 _nm Pixel electrode
28 _nm Counter electrode
30 Signal driver IC
32 Scan Driver IC
34 Power supply circuit
36 Common electrode drive circuit
38 Signal control circuit
40 Input latch circuit
42 Shift register
44 Line latch circuit
46 Latch circuit
48 Partial block selection register
50, 100, 120, 200, 300 Reference voltage generation circuit
52 DAC (voltage selection circuit)
54 Output control circuit
56 voltage follower circuit
58A, 58B Partial non-display area
60 Partial display area
70, 102 Ladder resistance circuit
72, 104, 214, 314 First switch circuit (SW1)
74, 106, 216, 316 Second switch circuit (SW2)
210 Ladder resistance circuit for positive polarity
212, 312 First ladder resistor circuit
220 Ladder resistance circuit for negative polarity
222, 322 Second ladder resistor circuit
224, 324 Third switch circuit (SW3)
226, 326 Fourth switch circuit (SW4)
310 Positive Resistance Low Resistance Ladder Resistance Circuit (First Low Resistance Ladder Resistance Circuit)
320 Low resistance ladder resistance circuit for negative polarity (second low resistance ladder resistance circuit)
330 High-resistance ladder resistor circuit for positive polarity (first high-resistance ladder resistor circuit)
332 Third ladder resistor circuit
334 Fifth switch circuit (SW5)
336 Sixth switch circuit (SW6)
340 High resistance ladder resistance circuit for negative polarity (second high resistance ladder resistance circuit)
342 Fourth ladder resistor circuit
344 Seventh switch circuit (SW7)
346 Eighth switch circuit (SW8)
B0 to Bj blocks
BLK0_PART to BLKj_PART Partial block selection data
ND ₁ ~ ND _4i 1st to 4th split nodes
VND1 to VNDi First to i-th reference voltage output nodes
VSW1 to VSW (4i) First to fourth i reference voltage output switch circuits

Claims (6)

A reference voltage generation circuit for generating a multi-valued reference voltage for generating a gamma-corrected gradation value based on gradation data,
A plurality of resistor circuits connected in series, and the voltages of the first to i-th (i is an integer of 2 or more) divided nodes divided by each resistor circuit are output as first to i-th reference voltages. Ladder resistance circuit,
A first switch circuit inserted between a first power supply line to which a first power supply voltage is supplied and one end of the ladder resistor circuit;
A second switch circuit inserted between a second power supply line to which a second power supply voltage is supplied and the other end of the ladder resistor circuit;
The jth reference voltage output switch circuit electrically connected to the jth (1 ≦ j ≦ i, j is an integer) divided node outputs the jth divided node and the jth reference voltage. first to i-th reference voltage output switch circuits inserted between j reference voltage output nodes,
At least one of the plurality of blocks according to the partial block selection data for setting the display line of the display panel corresponding to the signal electrode of each block to the display state or the non-display state for each block in units of the plurality of signal electrodes. If one block is set to display,
The first and second switch circuits and the first to i-th reference voltage output switch circuits are:
In a given drive period based on the first to i-th reference voltages, the first and second switch control signals are simultaneously turned on, and when the period other than the drive period is reached, the first And simultaneously turned off based on the second switch control signal,
When all the blocks are set in a non-display state by the partial block selection data for the plurality of blocks,
The first and second switch circuits and the first to i-th reference voltage output switch circuits are:
The reference voltage generating circuit, which is turned off by the first and second switch control signals regardless of the driving period and a period other than the driving period. In claim 1,
The first and second switch control signals are:
A reference voltage generation circuit generated by using an output enable signal for controlling driving to a signal electrode and a latch pulse signal indicating scanning cycle timing. A reference voltage generation circuit according to claim 1 or 2,
A voltage selection circuit for selecting a voltage based on gradation data from a multi-valued reference voltage generated by the reference voltage generation circuit;
A signal electrode driving circuit for driving the signal electrode using the voltage selected by the voltage selection circuit;
A display driving circuit comprising: A partial block selection register for holding partial block selection data for setting a display line of a display panel corresponding to the signal electrode of each block to a display state or a non-display state for each block having a plurality of signal electrodes as a unit; ,
The reference voltage generation circuit according to any one of claims 1 to 3, wherein a reference voltage for driving a corresponding signal electrode is generated based on the partial block selection data;
A voltage selection circuit for selecting a voltage based on gradation data from a multi-valued reference voltage generated by the reference voltage generation circuit;
A signal electrode driving circuit for driving the signal electrode using the voltage selected by the voltage selection circuit;
A display driving circuit comprising: A plurality of signal electrodes;
A plurality of scanning electrodes intersecting the plurality of signal electrodes;
Pixels specified by the plurality of signal electrodes and the plurality of scanning electrodes;
The display driving circuit according to claim 3 or 4, which drives the plurality of signal electrodes;
A scan electrode driving circuit for driving the plurality of scan electrodes;
A display device comprising: A plurality of signal electrodes;
A plurality of scanning electrodes intersecting the plurality of signal electrodes;
Pixels specified by the plurality of signal electrodes and the plurality of scanning electrodes;
A display panel including:
The display driving circuit according to claim 3 or 4, which drives the plurality of signal electrodes;
A scan electrode driving circuit for driving the plurality of scan electrodes;
A display device comprising:

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